Your search keyword '"Meeus, Marcel"' showing total 13 results

1. Safe-and-sustainable-by-design: State of the art approaches and lessons learned from value chain perspectives

Author

Apel, Christina, primary, Kümmerer, Klaus, additional, Sudheshwar, Akshat, additional, Nowack, Bernd, additional, Som, Claudia, additional, Colin, Catherine, additional, Walter, Lutz, additional, Breukelaar, Johan, additional, Meeus, Marcel, additional, Ildefonso, Beatriz, additional, Petrovykh, Dmitri, additional, Elyahmadi, Chaima, additional, Huttunen-Saarivirta, Elina, additional, Dierckx, Ann, additional, Devic, Anne Chloé, additional, Valsami-Jones, Eva, additional, Brennan, Maurice, additional, Rocca, Cris, additional, Scheper, Johanna, additional, Strömberg, Emma, additional, and Soeteman-Hernández, Lya G., additional

Published

2024

2. Primary zinc-air batteries

Author

Yadav, Gautam G., primary, Wei, Xia, additional, and Meeus, Marcel, additional

Published

2021

3. Recycling of Lithium-Ion Batteries-Current State of the Art, Circular Economy, and Next Generation Recycling

Author

Neumann, Jonas, Petranikova, Martina, Meeus, Marcel, Gamarra, Jorge D., Younesi, Reza, Winter, Martin, Nowak, Sascha, Neumann, Jonas, Petranikova, Martina, Meeus, Marcel, Gamarra, Jorge D., Younesi, Reza, Winter, Martin, and Nowak, Sascha

Abstract

Being successfully introduced into the market only 30 years ago, lithium-ion batteries have become state-of-the-art power sources for portable electronic devices and the most promising candidate for energy storage in stationary or electric vehicle applications. This widespread use in a multitude of industrial and private applications leads to the need for recycling and reutilization of their constituent components. Improving the "recycling technology" of lithium ion batteries is a continuous effort and recycling is far from maturity today. The complexity of lithium ion batteries with varying active and inactive material chemistries interferes with the desire to establish one robust recycling procedure for all kinds of lithium ion batteries. Therefore, the current state of the art needs to be analyzed, improved, and adapted for the coming cell chemistries and components. This paper provides an overview of regulations and new battery directive demands. It covers current practices in material collection, sorting, transportation, handling, and recycling. Future generations of batteries will further increase the diversity of cell chemistry and components. Therefore, this paper presents predictions related to the challenges of future battery recycling with regard to battery materials and chemical composition, and discusses future approaches to battery recycling.

Published

2022

4. A Roadmap for Transforming Research to Invent the Batteries of the Future Designed within the European Large Scale Research Initiative BATTERY 2030+

Author

Amici, Julia, Asinari, Pietro, Ayerbe, Elixabete, Barboux, Philippe, Bayle-Guillemaud, Pascale, Behm, R. Juergen, Berecibar, Maitane, Berg, Erik, Bhowmik, Arghya, Bodoardo, Silvia, Castelli, Ivano E., Cekic-Laskovic, Isidora, Christensen, Rune, Clark, Simon, Diehm, Ralf, Dominko, Robert, Fichtner, Maximilian, Franco, Alejandro A., Grimaud, Alexis, Guillet, Nicolas, Hahlin, Maria, Hartmann, Sarah, Heiries, Vincent, Hermansson, Kersti, Heuer, Andreas, Jana, Saibal, Jabbour, Lara, Kallo, Josef, Latz, Arnulf, Lorrmann, Henning, Lovvik, Ole Martin, Lyonnard, Sandrine, Meeus, Marcel, Paillard, Elie, Perraud, Simon, Placke, Tobias, Punckt, Christian, Raccurt, Olivier, Ruhland, Janna, Sheridan, Edel, Stein, Helge, Tarascon, Jean-Marie, Trapp, Victor, Vegge, Tejs, Weil, Marcel, Wenzel, Wolfgang, Winter, Martin, Wolf, Andreas, Edström, Kristina, Amici, Julia, Asinari, Pietro, Ayerbe, Elixabete, Barboux, Philippe, Bayle-Guillemaud, Pascale, Behm, R. Juergen, Berecibar, Maitane, Berg, Erik, Bhowmik, Arghya, Bodoardo, Silvia, Castelli, Ivano E., Cekic-Laskovic, Isidora, Christensen, Rune, Clark, Simon, Diehm, Ralf, Dominko, Robert, Fichtner, Maximilian, Franco, Alejandro A., Grimaud, Alexis, Guillet, Nicolas, Hahlin, Maria, Hartmann, Sarah, Heiries, Vincent, Hermansson, Kersti, Heuer, Andreas, Jana, Saibal, Jabbour, Lara, Kallo, Josef, Latz, Arnulf, Lorrmann, Henning, Lovvik, Ole Martin, Lyonnard, Sandrine, Meeus, Marcel, Paillard, Elie, Perraud, Simon, Placke, Tobias, Punckt, Christian, Raccurt, Olivier, Ruhland, Janna, Sheridan, Edel, Stein, Helge, Tarascon, Jean-Marie, Trapp, Victor, Vegge, Tejs, Weil, Marcel, Wenzel, Wolfgang, Winter, Martin, Wolf, Andreas, and Edström, Kristina

Abstract

This roadmap presents the transformational research ideas proposed by "BATTERY 2030+," the European large-scale research initiative for future battery chemistries. A "chemistry-neutral" roadmap to advance battery research, particularly at low technology readiness levels, is outlined, with a time horizon of more than ten years. The roadmap is centered around six themes: 1) accelerated materials discovery platform, 2) battery interface genome, with the integration of smart functionalities such as 3) sensing and 4) self-healing processes. Beyond chemistry related aspects also include crosscutting research regarding 5) manufacturability and 6) recyclability. This roadmap should be seen as an enabling complement to the global battery roadmaps which focus on expected ultrahigh battery performance, especially for the future of transport. Batteries are used in many applications and are considered to be one technology necessary to reach the climate goals. Currently the market is dominated by lithium-ion batteries, which perform well, but despite new generations coming in the near future, they will soon approach their performance limits. Without major breakthroughs, battery performance and production requirements will not be sufficient to enable the building of a climate-neutral society. Through this "chemistry neutral" approach a generic toolbox transforming the way batteries are developed, designed and manufactured, will be created.

Published

2022

5. Rechargeable Batteries of the Future-The State of the Art from a BATTERY 2030+Perspective

Author

Fichtner, Maximilian, Edström, Kristina, Ayerbe, Elixabete, Berecibar, Maitane, Bhowmik, Arghya, Castelli, Ivano E., Clark, Simon, Dominko, Robert, Erakca, Merve, Franco, Alejandro A., Grimaud, Alexis, Horstmann, Birger, Latz, Arnulf, Lorrmann, Henning, Meeus, Marcel, Narayan, Rekha, Pammer, Frank, Ruhland, Janna, Stein, Helge, Vegge, Tejs, Weil, Marcel, Fichtner, Maximilian, Edström, Kristina, Ayerbe, Elixabete, Berecibar, Maitane, Bhowmik, Arghya, Castelli, Ivano E., Clark, Simon, Dominko, Robert, Erakca, Merve, Franco, Alejandro A., Grimaud, Alexis, Horstmann, Birger, Latz, Arnulf, Lorrmann, Henning, Meeus, Marcel, Narayan, Rekha, Pammer, Frank, Ruhland, Janna, Stein, Helge, Vegge, Tejs, and Weil, Marcel

Abstract

The development of new batteries has historically been achieved through discovery and development cycles based on the intuition of the researcher, followed by experimental trial and error-often helped along by serendipitous breakthroughs. Meanwhile, it is evident that new strategies are needed to master the ever-growing complexity in the development of battery systems, and to fast-track the transfer of findings from the laboratory into commercially viable products. This review gives an overview over the future needs and the current state-of-the art of five research pillars of the European Large-Scale Research Initiative BATTERY 2030+, namely 1) Battery Interface Genome in combination with a Materials Acceleration Platform (BIG-MAP), progress toward the development of 2) self-healing battery materials, and methods for operando, 3) sensing to monitor battery health. These subjects are complemented by an overview over current and up-coming strategies to optimize 4) manufacturability of batteries and efforts toward development of a circular battery economy through implementation of 5) recyclability aspects in the design of the battery.

Published

2022

6. Rechargeable Batteries of the Future—The State of the Art from a BATTERY 2030+ Perspective

Author

Fichtner, Maximilian, Edström, Kristina, Ayerbe, Elixabete, Berecibar, Maitane, Bhowmik, Arghya, Castelli, Ivano E., Clark, Simon, Dominko, Robert, Erakca, Merve, Franco, Alejandro A., Grimaud, Alexis, Horstmann, Birger, Latz, Arnulf, Lorrmann, Henning, Meeus, Marcel, Narayan, Rekha, Pammer, Frank, Ruhland, Janna, Stein, Helge, Vegge, Tejs, Weil, Marcel, Fichtner, Maximilian, Edström, Kristina, Ayerbe, Elixabete, Berecibar, Maitane, Bhowmik, Arghya, Castelli, Ivano E., Clark, Simon, Dominko, Robert, Erakca, Merve, Franco, Alejandro A., Grimaud, Alexis, Horstmann, Birger, Latz, Arnulf, Lorrmann, Henning, Meeus, Marcel, Narayan, Rekha, Pammer, Frank, Ruhland, Janna, Stein, Helge, Vegge, Tejs, and Weil, Marcel

Abstract

The development of new batteries has historically been achieved through discovery and development cycles based on the intuition of the researcher, followed by experimental trial and error—often helped along by serendipitous breakthroughs. Meanwhile, it is evident that new strategies are needed to master the ever-growing complexity in the development of battery systems, and to fast-track the transfer of findings from the laboratory into commercially viable products. This review gives an overview over the future needs and the current state-of-the art of five research pillars of the European Large-Scale Research Initiative BATTERY 2030+, namely 1) Battery Interface Genome in combination with a Materials Acceleration Platform (BIG-MAP), progress toward the development of 2) self-healing battery materials, and methods for operando, 3) sensing to monitor battery health. These subjects are complemented by an overview over current and up-coming strategies to optimize 4) manufacturability of batteries and efforts toward development of a circular battery economy through implementation of 5) recyclability aspects in the design of the battery.

Published

2022

7. A Roadmap for Transforming Research to Invent the Batteries of the Future Designed within the European Large Scale Research Initiative BATTERY 2030+

Author

Amici, Julia, primary, Asinari, Pietro, additional, Ayerbe, Elixabete, additional, Barboux, Philippe, additional, Bayle‐Guillemaud, Pascale, additional, Behm, R. Jürgen, additional, Berecibar, Maitane, additional, Berg, Erik, additional, Bhowmik, Arghya, additional, Bodoardo, Silvia, additional, Castelli, Ivano E., additional, Cekic‐Laskovic, Isidora, additional, Christensen, Rune, additional, Clark, Simon, additional, Diehm, Ralf, additional, Dominko, Robert, additional, Fichtner, Maximilian, additional, Franco, Alejandro A., additional, Grimaud, Alexis, additional, Guillet, Nicolas, additional, Hahlin, Maria, additional, Hartmann, Sarah, additional, Heiries, Vincent, additional, Hermansson, Kersti, additional, Heuer, Andreas, additional, Jana, Saibal, additional, Jabbour, Lara, additional, Kallo, Josef, additional, Latz, Arnulf, additional, Lorrmann, Henning, additional, Løvvik, Ole Martin, additional, Lyonnard, Sandrine, additional, Meeus, Marcel, additional, Paillard, Elie, additional, Perraud, Simon, additional, Placke, Tobias, additional, Punckt, Christian, additional, Raccurt, Olivier, additional, Ruhland, Janna, additional, Sheridan, Edel, additional, Stein, Helge, additional, Tarascon, Jean‐Marie, additional, Trapp, Victor, additional, Vegge, Tejs, additional, Weil, Marcel, additional, Wenzel, Wolfgang, additional, Winter, Martin, additional, Wolf, Andreas, additional, and Edström, Kristina, additional

Published

2022

8. Recycling of Lithium‐Ion Batteries—Current State of the Art, Circular Economy, and Next Generation Recycling

Author

Neumann, Jonas, primary, Petranikova, Martina, additional, Meeus, Marcel, additional, Gamarra, Jorge D., additional, Younesi, Reza, additional, Winter, Martin, additional, and Nowak, Sascha, additional

Published

2022

9. Rechargeable Batteries of the Future—The State of the Art from a BATTERY 2030+ Perspective

Author

Fichtner, Maximilian, primary, Edström, Kristina, additional, Ayerbe, Elixabete, additional, Berecibar, Maitane, additional, Bhowmik, Arghya, additional, Castelli, Ivano E., additional, Clark, Simon, additional, Dominko, Robert, additional, Erakca, Merve, additional, Franco, Alejandro A., additional, Grimaud, Alexis, additional, Horstmann, Birger, additional, Latz, Arnulf, additional, Lorrmann, Henning, additional, Meeus, Marcel, additional, Narayan, Rekha, additional, Pammer, Frank, additional, Ruhland, Janna, additional, Stein, Helge, additional, Vegge, Tejs, additional, and Weil, Marcel, additional

Published

2021

10. Chapter 3 - Primary zinc-air batteries

Author

Yadav, Gautam G., Wei, Xia, and Meeus, Marcel

Published

2021

11. Sunrise Roadmap and Appendices

Author

Faber, Carina, Yagut Allahverdiyeva, Artero, Vincent, Baraton, Laurent, Barbieri, Andrea, Herve Bercegol, Fleischer, Maximilian, Huynhthi, Han, Kargul, Joanna, Lepaumier, Helene, Suarez, Laura Lopez, Magnuson, Ann, Braun, Artur, Roth, Arne, Armaroli, Nicola, Eva-Mari Aro, Baumann, Stefan, Cucurachi, Stefano, Durrant, James, Groot, Huub De, Hammarstrom, Leif, Jouhet, Juliette, Koch, Henrik, Mertens, Jan, Meeus, Marcel, Potter, Robert, Roeb, Martin, Schneider, Anita, Anonin Vlcek, Debajeet K Bora, Hongxin Wang, Lauterbach, Lars, and Joerg Pieper

Published

2020

12. Contributors

Author

Alcaide-Monterrubio, Francisco, Andersson, Stefan, Arai, Hajime, Cabot i Julià, Pere L., Clark, Simon, Fuchs, David, Heinzel, Angelika, Ishihara, Tatsumi, Jayasayee, Kaushik, Jensen, Ingvild Julie Thue, Jörissen, Ludwig, Juel, Mari, Kim, Hackho, Krebs, Martin, Mahlendorf, Falko, Meeus, Marcel, Miyazaki, Kohei, Mueller, Christoph, Nazar, Linda, Ponce de León, Reichardt, Hans-Ulrich, Sojka, Reiner, Stevens, Philippe, Wei, Xia, and Yadav, Gautam G.

Published

2021

13. Safe-and-sustainable-by-design: State of the art approaches and lessons learned from value chain perspectives

Author

Apel, Christina, Kümmerer, Klaus, Sudheshwar, Akshat, Nowack, Bernd, Som, Claudia, Colin, Catherine, Walter, Lutz, Breukelaar, Johan, Meeus, Marcel, Ildefonso, Beatriz, Petrovykh, Dmitri, Elyahmadi, Chaima, Huttunen-Saarivirta, Elina, Dierckx, Ann, Devic, Anne Chloé, Valsami-Jones, Eva, Brennan, Maurice, Rocca, Cris, Scheper, Johanna, Strömberg, Emma, and Soeteman-Hernández, Lya G.

Abstract

Safe-and-sustainable-by-design (SSbD) is central in the European Chemicals Strategy for Sustainability, yet a common understanding of what SSbD is in concept and in practice is still needed. A comparison of current SSbD descriptions and approaches was made and lessons learned were derived from value chain discussions (packaging, textile, construction, automotive, energy materials, electronics, and fragrances value chains) to help provide input on how to implement SSbD in practice. Five important building blocks were identified: design, data, risk and sustainability governance, competencies, and social and corporate strategic needs. Other lessons learned include the identification of the biggest safety and sustainability challenges in a lifecycle-thinking approach towards the development of purpose-driven innovations, and connecting trans-disciplinary experts to the innovation process, already from the early phases. A clear understanding of what SSbD is and how to implement the SSbD framework is needed with clear procedures and incentives to support the industrial sector, especially SMEs.

Published

2023